Your search keyword '"Abu-Yousif AO"' showing total 3 results

1. Increased Tumor Penetration of Single-Domain Antibody-Drug Conjugates Improves In Vivo Efficacy in Prostate Cancer Models.

Author

Nessler I, Khera E, Vance S, Kopp A, Qiu Q, Keating TA, Abu-Yousif AO, Sandal T, Legg J, Thompson L, Goodwin N, and Thurber GM

Subjects

Animals, Antineoplastic Agents, Alkylating chemistry, Antineoplastic Agents, Alkylating therapeutic use, Cell Line, Tumor, Computer Simulation, Humans, Immunoconjugates chemistry, Immunoconjugates therapeutic use, Male, Mice, Microscopy, Confocal, Prostatic Neoplasms diagnostic imaging, Prostatic Neoplasms pathology, Single-Domain Antibodies chemistry, Single-Domain Antibodies therapeutic use, Spheroids, Cellular, Structure-Activity Relationship, Tissue Distribution, Xenograft Model Antitumor Assays, Antineoplastic Agents, Alkylating pharmacology, Immunoconjugates pharmacokinetics, Models, Biological, Prostatic Neoplasms drug therapy, Single-Domain Antibodies pharmacology

Abstract

Targeted delivery of chemotherapeutics aims to increase efficacy and lower toxicity by concentrating drugs at the site-of-action, a method embodied by the seven current FDA-approved antibody-drug conjugates (ADC). However, a variety of pharmacokinetic challenges result in relatively narrow therapeutic windows for these agents, hampering the development of new drugs. Here, we use a series of prostate-specific membrane antigen-binding single-domain (Humabody) ADC constructs to demonstrate that tissue penetration of protein-drug conjugates plays a major role in therapeutic efficacy. Counterintuitively, a construct with lower in vitro potency resulted in higher in vivo efficacy than other protein-drug conjugates. Biodistribution data, tumor histology images, spheroid experiments, in vivo single-cell measurements, and computational results demonstrate that a smaller size and slower internalization rate enabled higher tissue penetration and more cell killing. The results also illustrate the benefits of linking an albumin-binding domain to the single-domain ADCs. A construct lacking an albumin-binding domain was rapidly cleared, leading to lower tumor uptake (%ID/g) and decreased in vivo efficacy. In conclusion, these results provide evidence that reaching the maximum number of cells with a lethal payload dose correlates more strongly with in vivo efficacy than total tumor uptake or in vitro potency alone for these protein-drug conjugates. Computational modeling and protein engineering can be used to custom design an optimal framework for controlling internalization, clearance, and tissue penetration to maximize cell killing. SIGNIFICANCE: A mechanistic study of protein-drug conjugates demonstrates that a lower potency compound is more effective in vivo than other agents with equal tumor uptake due to improved tissue penetration and cellular distribution., (©2020 American Association for Cancer Research.)

Published

2020

2. Killing hypoxic cell populations in a 3D tumor model with EtNBS-PDT.

Author

Evans CL, Abu-Yousif AO, Park YJ, Klein OJ, Celli JP, Rizvi I, Zheng X, and Hasan T

Subjects

Carboplatin pharmacology, Cell Death drug effects, Cell Death radiation effects, Cell Hypoxia drug effects, Cell Hypoxia radiation effects, Cell Line, Tumor, Cell Survival drug effects, Cell Survival radiation effects, Drug Resistance, Neoplasm drug effects, Drug Resistance, Neoplasm radiation effects, Drug Screening Assays, Antitumor, Humans, Light, Neoplasm Metastasis, Photosensitizing Agents pharmacology, Photosensitizing Agents therapeutic use, Porphyrins pharmacology, Porphyrins therapeutic use, Thiazines pharmacology, Treatment Outcome, Verteporfin, Models, Biological, Neoplasms drug therapy, Neoplasms pathology, Photochemotherapy, Thiazines therapeutic use

Abstract

An outstanding problem in cancer therapy is the battle against treatment-resistant disease. This is especially true for ovarian cancer, where the majority of patients eventually succumb to treatment-resistant metastatic carcinomatosis. Limited perfusion and diffusion, acidosis, and hypoxia play major roles in the development of resistance to the majority of front-line therapeutic regimens. To overcome these limitations and eliminate otherwise spared cancer cells, we utilized the cationic photosensitizer EtNBS to treat hypoxic regions deep inside in vitro 3D models of metastatic ovarian cancer. Unlike standard regimens that fail to penetrate beyond ∼150 µm, EtNBS was found to not only penetrate throughout the entirety of large (>200 µm) avascular nodules, but also concentrate into the nodules' acidic and hypoxic cores. Photodynamic therapy with EtNBS was observed to be highly effective against these hypoxic regions even at low therapeutic doses, and was capable of destroying both normoxic and hypoxic regions at higher treatment levels. Imaging studies utilizing multiphoton and confocal microscopies, as well as time-lapse optical coherence tomography (TL-OCT), revealed an inside-out pattern of cell death, with apoptosis being the primary mechanism of cell killing. Critically, EtNBS-based photodynamic therapy was found to be effective against the model tumor nodules even under severe hypoxia. The inherent ability of EtNBS photodynamic therapy to impart cytotoxicity across a wide range of tumoral oxygenation levels indicates its potential to eliminate treatment-resistant cell populations.

Published

2011

3. Quantitative imaging reveals heterogeneous growth dynamics and treatment-dependent residual tumor distributions in a three-dimensional ovarian cancer model.

Author

Celli JP, Rizvi I, Evans CL, Abu-Yousif AO, and Hasan T

Subjects

Antineoplastic Agents therapeutic use, Carboplatin therapeutic use, Cell Line, Tumor, Collagen, Drug Combinations, Female, Humans, Imaging, Three-Dimensional, Laminin, Microscopy, Confocal methods, Neoplasm, Residual, Optical Phenomena, Ovarian Neoplasms drug therapy, Photochemotherapy, Proteoglycans, Spheroids, Cellular drug effects, Spheroids, Cellular pathology, Time-Lapse Imaging, Models, Biological, Ovarian Neoplasms pathology

Abstract

Three-dimensional tumor models have emerged as valuable in vitro research tools, though the power of such systems as quantitative reporters of tumor growth and treatment response has not been adequately explored. We introduce an approach combining a 3-D model of disseminated ovarian cancer with high-throughput processing of image data for quantification of growth characteristics and cytotoxic response. We developed custom MATLAB routines to analyze longitudinally acquired dark-field microscopy images containing thousands of 3-D nodules. These data reveal a reproducible bimodal log-normal size distribution. Growth behavior is driven by migration and assembly, causing an exponential decay in spatial density concomitant with increasing mean size. At day 10, cultures are treated with either carboplatin or photodynamic therapy (PDT). We quantify size-dependent cytotoxic response for each treatment on a nodule by nodule basis using automated segmentation combined with ratiometric batch-processing of calcein and ethidium bromide fluorescence intensity data (indicating live and dead cells, respectively). Both treatments reduce viability, though carboplatin leaves micronodules largely structurally intact with a size distribution similar to untreated cultures. In contrast, PDT treatment disrupts micronodular structure, causing punctate regions of toxicity, shifting the distribution toward smaller sizes, and potentially increasing vulnerability to subsequent chemotherapeutic treatment.

Published

2010